Fire Alarm Control Panel AM2020/AFP1010. Document /22/99 Rev: P/N 15088:J ECN

Fire Alarm Control Panel AM2020/AFP1010 Document 15088 10/22/99 Rev: J P/N 15088:J ECN 99-521

Fire Alarm System Limitations An automatic fire alarm system typically made up of smoke detectors, heat detectors, manual pull stations, audible warning devices, and a fire alarm control with remote notification capability can provide early warning of a developing fire. Such a system, however, does not assure protection against property damage or loss of life resulting from a fire. The Manufacturer recommends that smoke and/or heat detectors be located throughout a protected premise following the recommendations of the current edition of the National Fire Protection Association Standard 72 (NFPA 72), manufacturer's recommendations, State and local codes, and the recommendations contained in the Guide for Proper Use of System Smoke Detectors, which is made available at no charge to all installing dealers. A study by the Federal Emergency Management Agency (an agency of the United States government) indicated that smoke detectors may not go off in as many as 35% of all fires. While fire alarm systems are designed to provide early warning against fire, they do not guarantee warning or protection against fire. A fire alarm system may not provide timely or adequate warning, or simply may not function, for a variety of reasons: Smoke detectors may not sense fire where smoke cannot reach the detectors such as in chimneys, in or behind walls, on roofs, or on the other side of closed doors. Smoke detectors also may not sense a fire on another level or floor of a building. A second-floor detector, for example, may not sense a first-floor or basement fire. Particles of combustion or "smoke" from a developing fire may not reach the sensing chambers of smoke detectors because: Barriers such as closed or partially closed doors, walls, or chimneys may inhibit particle or smoke flow. Smoke particles may become "cold," stratify, and not reach the ceiling or upper walls where detectors are located. Smoke particles may be blown away from detectors by air outlets. Smoke detectors may be drawn into air returns before reaching the detector. The amount of "smoke" present may be insufficient to alarm smoke detectors. Smoke detectors are designed to alarm at various levels of smoke density. If such density levels are not created by a developing fire at the location of detectors, the detectors will not go into alarm. Smoke detectors, even when working properly, have sensing limitations. Detectors that have photoelectronic sensing chambers tend to detect smoldering fires better than flaming fires, which have little visible smoke. Detectors that have ionizing-type sensing chambers tend to detect fast-flaming fires better than smoldering fires. Because fires develop in different ways and are often unpredictable in their growth, neither type of detector is necessarily best and a given type of detector may not provide adequate warning of a fire. Smoke detectors cannot be expected to provide adequate warning of fires caused by arson, children playing with matches (especially in bedrooms), smoking in bed, and violent explosions (caused by escaping gas, improper storage of flammable materials, etc.). While a fire alarm system may lower insurance rates, it is not a substitute for fire insurance! Heat detectors do not sense particles of combustion and alarm only when heat on their sensors increases at a predetermined rate or reaches a predetermined level. Rate-of-rise heat detectors may be subject to reduced sensitivity over time. For this reason, the rate-of-rise feature of each detector should be tested at least once per year by a qualified fire protection specialist. Heat detectors are designed to protect property, not life. IMPORTANT! Smoke detectors must be installed in the same room as the control panel and in rooms used by the system for the connection of alarm transmission wiring, communications, signaling, and/or power. If detectors are not so located, a developing fire may damage the alarm system, crippling its ability to report a fire. Audible warning devices such as bells may not alert people if these devices are located on the other side of closed or partly open doors or are located on another floor of a building. Any warning device may fail to alert people with a disability or those who have recently consumed drugs, alcohol or medication. Please note that: Strobes can, under certain circumstances, cause seizures in people with conditions such as epilepsy. Studies have shown that certain people, even when they hear a fire alarm signal, do not respond or comprehend the meaning of the signal. It is the property owner's responsibility to conduct fire drills and other training exercise to make people aware of fire alarm signals and instruct them on the proper reaction to alarm signals. In rare instances, the sounding of a warning device can cause temporary or permanent hearing loss. A fire alarm system will not operate without any electrical power. If AC power fails, the system will operate from standby batteries only for a specified time and only if the batteries have been properly maintained and replaced regularly. Equipment used in the system may not be technically compatible with the control. It is essential to use only equipment listed for service with your control panel. Telephone lines needed to transmit alarm signals from a premise to a central monitoring station may be out of service or temporarily disabled. For added protection against telephone line failure, backup radio transmission systems are recommended. The most common cause of fire alarm malfunction is inadequate maintenance. To keep the entire fire alarm system in excellent working order, ongoing maintenance is required per the manufacturer's recommendations, and UL and NFPA standards. At a minimum, the requirements of Chapter 7 of NFPA 72 shall be followed. Environments with large amounts of dust, dirt or high air velocity require more frequent maintenance. A maintenance agreement should be arranged through the local manufacturer's representative. Maintenance should be scheduled monthly or as required by National and/ or local fire codes and should be performed by authorized professional fire alarm installers only. Adequate written records of all inspections should be kept. LimWarLg.p65 01/10/2000

Installation Precautions WARNING - Several different sources of power can be connected to the fire alarm control panel. Disconnect all sources of power before servicing. Control unit and associated equipment may be damaged by removing and/or inserting cards, modules, or interconnecting cables while the unit is energized. Do not attempt to install, service, or operate this unit until this manual is read and understood. CAUTION - System Reacceptance Test after Software Changes. To ensure proper system operation, this product must be tested in accordance with NFPA 72 Chapter 7 after any programming operation or change in site-specific software. Reacceptance testing is required after any change, addition or deletion of system components, or after any modification, repair or adjustment to system hardware or wiring. All components, circuits, system operations, or software functions known to be affected by a change must be 100% tested. In addition, to ensure that other operations are not inadvertently affected, at least 10% of initiating devices that are not directly affected by the change, up to a maximum of 50 devices, must also be tested and proper system operation verified. This system meets NFPA requirements for operation at 0-49 C/32-120 F and at a relative humidity of 85% RH (noncondensing) at 30 C/86 F. However, the useful life of the system's standby batteries and the electronic components may be adversely affected by extreme temperature ranges and humidity. Therefore, it is recommended that this system and all peripherals be installed in an environment with a nominal room temperature of 15-27 C/60-80 F. Verify that wire sizes are adequate for all initiating and indicating device loops. Most devices cannot tolerate more than a 10% I.R. drop from the specified device voltage. Adherence to the following will aid in problem-free installation with long-term reliability: Like all solid state electronic devices, this system may operate erratically or can be damaged when subjected to lightning-induced transients. Although no system is completely immune from lightning transients and interferences, proper grounding will reduce susceptibility. Overhead or outside aerial wiring is not recommended, due to an increased susceptibility to nearby lightning strikes. Consult with the Technical Services Department if any problems are anticipated or encountered. Disconnect AC power and batteries prior to removing or inserting circuit boards. Failure to do so can damage circuits. Remove all electronic assemblies prior to any drilling, filing, reaming, or punching of the enclosure. When possible, make all cable entries from the sides or rear. Before making modifications, verify that they will not interfere with battery, transformer, and printed circuit board location. Do not tighten screw terminals more than 9 in-lbs. Over-tightening may damage threads, resulting in reduced terminal contact pressure and difficulty with screw terminal removal. Though designed to last many years, system components can fail at any time. This system contains static-sensitive components. Always ground yourself with a proper wrist strap before handling any circuits so that static charges are removed from the body. Use static-suppressive packaging to protect electronic assemblies removed from the unit. Follow the instructions in the installation, operating, and programming manuals. These instructions must be followed to avoid damage to the control panel and associated equipment. FACP operation and reliability depend upon proper installation by authorized personnel. FCC Warning WARNING: This equipment generates, uses, and can radiate radio frequency energy and if not installed and used in accordance with the instruction manual, may cause interference to radio communications. It has been tested and found to comply with the limits for class A computing device pursuant to Subpart B of Part 15 of FCC Rules, which is designed to provide reasonable protection against such interference when operated in a commercial environment. Operation of this equipment in a residential area is likely to cause interference, in which case the user will be required to correct the interference at his own expense. Canadian Requirements This digital apparatus does not exceed the Class A limits for radiation noise emissions from digital apparatus set out in the Radio Interference Regulations of the Canadian Department of Communications. Le present appareil numerique n'emet pas de bruits radioelectriques depassant les limites applicables aux appareils numeriques de la classe A prescrites dans le Reglement sur le brouillage radioelectrique edicte par le ministere des Communications du Canada. LimWarLg.p65 01/10/2000

TABLE OF CONTENTS Chapter One Installation Introduction... 1-3 Capabilities and Capacities... 1-3 Fire Alarm and Related Service Standards... 1-4 Section One Installation Overview... 1-5 Section 1.1 Basic Equipment... 1-5 Section 1.2 Related Documentation... 1-5 Table 1.2-1 AM2020/AFP1010 Related Documentation... 1-6 Section Two Cabinets... 1-7 Section 2.1 Mounting the Backbox... 1-8 Figure 2.1-1 Cabinet Backbox Mount... 1-8 Section 2.2 CAB-3 Series Backboxes... 1-11 Section 2.3 Mounting the ICA-4L... 1-13 Figure 2.3-1 ICA-4L 16 Position Receptacle Connections... 1-13 Figure 2.3-2 Expansion Power Cable Part Number 75378... 1-13 Figure 2.3-3 Connecting Two ICA-4Ls... 1-14 Figure 2.3-4 Power Cable Part Number 75379... 1-15 Figure 2.3-5 15 Position Receptacle Connections... 1-15 Figure 2.3-6 Cable Part Number 75142... 1-16 Figure 2.3-7 Cable Part Number 75142 Connected to the ICA-4L... 1-16 Figure 2.3-8 Mount System Boards to the ICA-4L Chassis... 1-17 Section 2.4 Component Placement... 1-18 Table 2.4-1 Cabinet Size Information... 1-18 Figure 2.4-1 Component Placement Guidelines... 1-18 Figure 2.4-2 AFP1010 LIB SLC Numbering Scheme... 1-19 Figure 2.4-3 LIB SLC Numbering Scheme... 1-20 Figure 2.4-4 LIB-400 Placement in an AFP1010... 1-21 Figure 2.4-5 LIB Placement Example in an AFP1010... 1-22 Figure 2.4-6 LIB-400 Placement in an AM2020... 1-23 Figure 2.4-7 LIB Placement Example in an AM2020... 1-24 Section 2.5 Optional Chassis Mounting... 1-25 Figure 2.5-1 Optional Chassis Mount... 1-25 Section 2.6 Other Components... 1-26 Figure 2.6-1 Intelligent Fire Detection and Alarm System... 1-26 Section 2.7 Display Interface Connection... 1-27 Figure 2.7-1 Display Interface Assembly... 1-27 Figure 2.7-2 Wiring Placement Diagram... 1-28 Figure 2.7-3 Power-Limited and Non Power-Limited Wiring... `1-29 Figure 2.7-4 Dress Panel Placement Diagram... 1-30 Section 2.8 Mounting the MOD-1 into the CHS-4 and CHS-4L Chassis... 1-31 Figure 2.8-1 Mounting the MOD-1 into the CHS-4 and CHS-4L Chassis... 1-32 Section Three Power Supplies... 1-33 Section 3.1 The AC Primary Power Input... 1-33 Table 3.1-1 120 VAC Fire Alarm Circuit... 1-33 Table 3.1-2 220/240 VAC Fire Alarm Circuit... 1-33 Section 3.2 The MPS-24A or MPS-24AE Main Power Supply... 1-33 Table 3.2-1 AM2020/AFP1010 System Current Draw Calculations (1 of 2)... 1-35 Table 3.2-1 AM2020/AFP1010 System Current Draw Calculations (2 of 2)... 1-36 Table 3.2-2 Maximum Secondary Power Fire Alarm Current Draw... 1-37 iv AM2020/AFP1010 15088:J 10/22/99

CHAPTER ONE INSTALLATION (CONTINUED) Table 3.2-3 Secondary Power Standby and Fire Alarm Load... 1-37 Table 3.2-4 Battery Size Requirements... 1-38 Figure 3.2-1 Mount the Main Power Supply... 1-39 Section 3.2.1 The MPS-TR Main Power Supply... 1-40 Figure 3.2.1-1 Threading the Screws... 1-40 Figure 3.2.1-2 Mounting the MPS-TR... 1-41 Figure 3.2.1-3 System Common Terminal Connection... 1-41 Section 3.3 Connecting the Main Power Supply... 1-42 Table 3.3-1 MPS-24A or MPS-24AE Main Power Supply Loads... 1-43 Figure 3.3-1 Field Wiring the MPS-24A or MPS-24AE Power Supply... 1-44 Section 3.4 The Optional Main Power Meter... 1-45 Figure 3.4-1 Installation of the Main Power Meter... 1-45 Section 3.5 The CHG-120 Remote Battery Charger... 1-46 Figure 3.5-1 CHG-120 Installation into CAB-3 Series (3.6-1a) and BB-55 (3.6-1b) Cabinets... 1-46 Figure 3.5-2 CHG-120 Connections... 1-46 Section 3.6 The APS-6R Auxiliary Power Supply... 1-47 Figure 3.6-1 Mounting the APS-6R to a Chassis... 1-48 Figure 3.6-2 Cover Installations... 1-48 Figure 3.6-3 Typical APS-6R Wiring... 1-48 Figure 3.6-4 Trouble Bus Connections for Multiple APS-6R Power Supply Configurations... 1-49 Section 3.7 The Central Processing Unit (CPU-2020, CPU-2)... 1-50 Figure 3.7-1 CPU Alarm and Trouble Contacts... 1-50 Section Four Signaling... 1-51 Section 4.1 The LIB Signaling Line Circuit... 1-51 Section 4.2 The Loop Interface Boards (LIB-200, LIB-200A, and LIB-400)... 1-52 Figure 4.2-1 The LIB-200... 1-52 Figure 4.2-2 Loop Interface Boards... 1-54 Figure 4.2-3 Surge Suppressor/FACP Connections... 1-55 Section 4.3 LIB SLC Loop Wiring Requirements... 1-56 Figure 4.3-1 SLC Loop Wiring Requirements (Style 4)... 1-56 Figure 4.3-2 SLC Loop Wiring Requirements (Style 6)... 1-57 Figure 4.3-3 Typical NFPA Style 4 SLC Loops... 1-58 Figure 4.3-4 NFPA Style 6 LIB SLC Loop... 1-59 Figure 4.3-5 NFPA Style 7 SLC... 1-60 Section 4.4 SLC Loop Shield Termination (Optional)... 1-61 Figure 4.4-1 Shield Termination in No Conduit... 1-61 Figure 4.4-2 Shield Termination in Full conduit (LIB-200 only)... 1-61 Figure 4.4-2 Shield Termination in Partial Conduit (LIB-200 only)... 1-62 Section 4.5 The Isolator Module... 1-63 Figure 4.5-1 The Loop Isolator Module (ISO-X)... 1-63 Figure 4.5-2 Isolating a Branch of a Style 4 SLC Loop... 1-63 Figure 4.5-3 Isolating the Remainder of a Style 4 SLC Loop... 1-63 Section 4.6 Monitor Modules... 1-65 Figure 4.6-1 MMX-1 or MMX-2 Monitor Modules... 1-65 Figure 4.6-2 MMX-101 Monitor Module... 1-65 Figure 4.6-3 NFPA Style B Initiating Device Circuit... 1-66 Figure 4.6-4 NFPA Style D Initiating Device Circuit... 1-67 Figure 4.6-5 Employing Four-Wire Smoke Detectors (Style B IDC)... 1-68 Figure 4.6-6 Employing Four-Wire Smoke Detectors (Style D IDC)... 1-69 AM2020/AFP1010 15088:J 10/22/99 v

CHAPTER ONE INSTALLATION (CONTINUED) Section 4.7 The Control Module... 1-70 Figure 4.7-1 The CMX Control Module... 1-70 Figure 4.7-2 Providing Power to Control Modules... 1-71 Figure 4.7-3 Power Distribution... 1-72 Figure 4.7-4 NFPA Style Y Notification Appliance Circuit... 1-73 Figure 4.7-5 NFPA Style Z Notification Appliance Circuit... 1-74 Figure 4.7-6 Using the CMX as a Form-C Relay... 1-75 Figure 4.7-7 Typical APS-6R Wiring to a CMX Module... 1-75 Section 4.8 The Addressable Manual Pull Station... 1-76 Figure 4.8-1 Addressable Manual Pull Station... 1-76 Figure 4.8-2 Wiring Addressable Pull Stations... 1-76 Section 4.9 Intelligent Detectors... 1-77 Section 4.10 Smoke Detector Installation... 1-78 Figure 4.10-1 Wiring the Smoke Detector Base... 1-78 Figure 4.10-2 Wiring the B524BI Isolator Base... 1-79 Figure 4.10-3 Wiring the B524RB Relay Base... 1-79 Figure 4.10-4 Typical SLC Loop (Style 4)... 1-80 Section 4.11 The XP Series Transponder... 1-81 Figure 4.11-1 XP Dress Panel and XPP-1 Module... 1-81 Section Five Serial Communications... 1-83 Section 5.1 Optional Serial Interface Boards... 1-83 Figure 5.1-1 Male DB-25 Connector... 1-83 Figure 5.1-2 Guidelines for Terminating the Shield... 1-84 Figure 5.1-3 SIB-NET/SIB-2048A Terminal Designations... 1-85 Section 5.2 The CRT-2 Terminal... 1-86 Figure 5.2-1 CRT to SIB Connections... 1-87 Section 5.3 Remote Printers... 1-88 Figure 5.3-1 Remote Printer to SIB Connections... 1-88 Figure 5.3-2 Keltron Printer Connections... 1-89 Section 5.4 Annunciator Modules... 1-90 Figure 5.4-1 EIA-485 to SIB Connections... 1-91 Section Six Standard-Specific Requirements... 1-92 Section 6.1 NFPA 72-1993 Auxiliary Fire Alarm Systems... 1-94 Figure 6.1-1 Auxiliary Fire Alarm System (Fire Alarm Signal Transmission)... 1-94 Section 6.2 Generating Event-Pending Signals at a Remote Location... 1-95 Section 6.3 Supervising an Uninterruptable Power Supply... 1-96 Figure 6.3-1 Uninterruptable Power Supply... 1-96 Section 6.4 NFPA 72-1993 Proprietary Fire Alarm Systems... 1-97 Table 6.4-1 NIB-96 (Minimal Configuration)... 1-97 Figure 6.4-1 Proprietary Fire Alarm Systems... 1-98 Figure 6.4-2 NFPA 72-1993 Proprietary and Central Station Protected Premises Unit/ Proprietary and Central Station Receiving Unit Interface... 1-99 Section 6.5 Applying/Removing Power to the Fire Alarm System... 1-100 vi AM2020/AFP1010 15088:J 10/22/99

Chapter Two Operation Introduction... 2-2 Section One The Display Interface Assembly... 2-8 Section 1.1 Normal Operation...2-8 Section 1.2 Read Status... 2-10 Display System Configuration... 2-11 Point Read... 2-14 Special Status... 2-16 Section Two Prior/Next/Auto Step... 2-17 Section Three Special Function... 2-18 Reports... 2-18 Figure 3-1 AM2020/AFP1010 Special Function Report Printout... 2-19 The History Buffer... 2-20 Figure 3-2 AM2020/AFP1010 Special Function History Buffer Printout... 2-21 Section Four Fire Alarms... 2-22 Section 4.1 Acknowledging a Fire Alarm... 2-23 Section Five Troubles... 2-24 Section 5.1 Trouble...with SLC Loop Devices... 2-24 Section 5.2 Trouble...with Disabled Zones... 2-25 Section 5.3 Trouble...with the AM2020/AFP1010 System...2-26 Section 5.4 Trouble...with the Annunciators... 2-26 Section 5.5 Block Acknowledge... 2-27 Section 5.5A Acknowledging Troubles in Receiving Unit Mode... 2-28 Section 5.6 Displaying Current Alarms and Troubles... 2-28 Section Six Remote Peripherals... 2-29 Section Seven Trouble Messages... 2-30 Section Eight Drift Compensation... 2-32 AM2020/AFP1010 15088:J 10/22/99 vii

Chapter Three Programming Introduction... 3-3 The Initial Programming Outline... 3-5 Section One Main Programming... 3-7 Figure 1-1 Main Programming Menu Flow Chart... 3-8 Section 1.1 Partial System Programming... 3-9 Figure 1-2 Partial System Programming Submenu Flow Chart... 3-10 Section 1.1.1 LIB Installation... 3-11 Section 1.1.2 LIB SLC Loop Style... 3-11 Figure 1-3 Install Option Flow Chart... 3-11 Figure 1-4 Style Option Flow Chart... 3-11 Section 1.1.3 Time Delays... 3-12 Figure 1-5 Time Delay Option Flow Chart... 3-12 Section 1.1.4 Enabling the Trouble Bus... 3-13 Section 1.1.5 Zone Boundary... 3-13 Section 1.1.6 External Equipment... 3-14 Figure 1-6 External Equipment Option Flow Chart... 3-15 Section 1.1.7 Local Parameters... 3-18 Figure 1-7 Local Parameter Option Flow Chart... 3-18 Table 1-1 Extended Local Mode Categories and Software Type I.D.s... 3-20 Section 1.1.8 Intelligent Serial Interface Board Programming... 3-22 Figure 1-8 Intelligent Serial Interface Board Option Flow Chart... 3-22 Section 1.1.9 Additional System Parameters... 3-25 Figure 1-9 Additional System Parameters Option Flow Chart... 3-25 Section 1.2 Full System Programming... 3-28 Section 1.3 Partial Point Programming... 3-30 Figure 1-10 Partial Point Programming Flow Chart... 3-31 Section 1.3.1 Type I.D.... 3-31 Section 1.3.2 Control-By-Event... 3-32 Section 1.3.3 Label... 3-32 Section 1.3.4 Optional Features... 3-33 Figure 1-11 Optional Features Flow Chart... 3-33 Section 1.3.5 Annunciator Mapping... 3-34 Figure 1-12 Annunciator Mapping Option Flow Chart... 3-34 Section 1.3.6 Cooperative Control-By-Event... 3-35 Section 1.4 Full Point Programming... 3-36 Figure 1-13 Full Point Programming Flow Chart... 3-36 Section 1.5 Remove... 3-39 Section 1.6 Password... 3-39 Section 1.7 Message... 3-39 Section 1.8 History Mode... 3-40 Figure 1-14 History Buffer Option Flow Chart... 3-40 Section Two The Alter Status Menu... 3-43 Figure 2-1 Alter Status Menu Flow Chart... 3-44 Section 2.1 Disable Point... 3-44 Section 2.2 Control Module... 3-45 Section 2.3 Detector Sensitivity... 3-45 Section 2.4 Time... 3-45 Section 2.5 Diagnostics... 3-46 Section 2.6 Walk Test... 3-46 Figure 2-2 Walk Test Option Flow Chart... 3-47 Figure 2-3 Printout of an AM2020/AFP1010 Walk Test Report... 3-50 Section 2.7 Group Zone Disable... 3-51 viii AM2020/AFP1010 15088:J 10/22/99

Section Three Software Type I.D.s... 3-52 Section Four Control-by-Event Programming... 3-59 Section 4.1 Control-By-Event Programming... 3-59 Section 4.2 Operators... 3-61 Section 4.3 Size Limitations... 3-65 Section 4.4 Cooperative Control-By-Event... 3-67 Section 4.5 The Null Control-By-Event... 3-67 Section 4.6 Programming Examples... 3-68 Section Five Dual Stage Alert/Evacuation... 3-72 CHAPTER FOUR SECURITY Section One Installing and Programming Combination Fire/Security FireAlarm Systems... 4-3 Section 1.1 Introduction... 4-3 Section 1.2 General Security Requirements... 4-3 Section 1.3 Security Configuration - Specific Requirements... 4-4 Table 1.3-1 Building Perimeter Security Devices... 4-4 Table 1.3-2 Interior Space Security Devices... 4-5 Table 1.3-3 Zone numbers - One Set of Zones... 4-6 Table 1.3-4 Zone Numbers - Two Sets of Zones... 6-4 Figure 1.3-1 Simplest Security System... 4-7 Figure 1.3-2 Multiple Tenant Simple Security System... 4-8 Figure 1.3-3 Multiple Tenant Simple Security System... 4-9 Figure 1.3-4 Single Tenant Consolidated Security System... 4-10 Figure 1.3-5 Multiple Tenant consolidated Security System... 4-12 Figure 1.3-6 Single Tenant Security System with Entry/Exit Delay... 4-13 Figure 1.3-7 Connecting an MMX-101 Module to the RKS-S... 4-16 Figure 1.3-8 Connecting an MMX-1 to the RKS-S... 4-16 Figure 1.3-9 Multiple Tenant Security System with Entry/Exit Delay... 4-17 Figure 1.3-10 Single Tenant Security System with Ringback... 4-19 Figure 1.3-11 CMX Control Module for Ringback... 4-26 Figure 1.3-12 Installing an STS-1 Security Tamper Switch... 4-26 Figure 1.3-13 Connecting an STS-1 Switch to an MMX-101 Monitor Module... 4-27 Figure 1.3-14 Connecting an STS-1 Switch to an MMX-1 Monitor Module... 4-27 Figure 1.3-15 Multiple Tenant with Security System for Ringback... 4-28 Figure 1.3-16 System Requirements... 4-29 APPENDICES Appendix A Circuit/Device Ratings... A-3 Section A.1 Design Considerations... A-3 Table A-1 Wiring Selection Chart... A-3 Table A-2 Circuit Ratings/Connections... A-4 Appendix B Listed Equipment... B-1 Section B.1 Underwriter's Laboratories... B-1 Section B.2 Factory Mutual... B-2 Section B.3 Lloyd's Register... B-3 Section B.4 United States Coast Guard... B-4 Section B.5 Optional System Components... B-5 Section B.6 City of New York... B-6 PROGRAMMING SHEETS & GLOSSARY Programming Sheets... G-2 Glossary of Terms and Abbreviations... G-6 AM2020/AFP1010 15088:J 10/22/99 ix

Notes x AM2020/AFP1010 15088:J 10/22/99

AM2020 AFP1010 Chapter One Installation Installation 15088: J 10/22/99 1-1

1-2 Installation 15088:J 10/22/99

Introduction Capabilities and Capacities The AM2020/AFP1010 is an Intelligent Analog Addressable Combination Fire Alarm/Security Control Panel capable of supporting the following: Intelligent Analog Addressable Fire Detectors Photoelectric, ionization, and thermal (heat) detectors. Intelligent Addressable Fire and Security Initiating Devices Pull Stations and modules that monitor any conventional normally open contact type devices (4-wire smoke detectors, heat detectors, pull stations, supervisory switches, water flow switches), 2-wire conventional smoke detectors or any normally closed contact type device, such as a door contact that may be used in security applications. Intelligent Addressable Notification Devices and Addressable Control Relays Modules that can supervise and switch power to notification appliances or serve as Form-C control relays. Notification Appliance Power Notification appliance power is provided by the main power supply. Additional notification appliance power may be provided by optional power supplies listed for fire protective signaling. Voice Evacuation Functions Prerecorded or live voice alarm messages can be dispatched through an audio message generator. A fire fighter's master telephone unit allows communication between the control panel and fire fighter's telephones installed throughout the system. Audio Amplifier Power Audio power is provided by several sizes of audio amplifiers for use in voice alarm applications. Peripherals An AM2020/AFP1010 system can support remotely-mounted video display units, printers, and serial annunciators. AM2020 Maximum Intelligent Addressable Device Capacity (10 LIB-200/LIB-200A or five LIB-400 modules) 990 Intelligent photoelectric, ionization, and thermal (heat) detectors. + 990 Addressable pull stations, monitor modules, control modules and XP Transponder circuits. = 1980 Addressable devices system wide. AFP1010 Maximum Intelligent Addressable Device Capacity (four LIB-200/LIB-200A or two LIB-400 modules) 396 Intelligent photoelectric, ionization, and thermal (heat) detectors. + 396 Addressable pull stations, monitor modules, control modules and XP Transponder circuits. = 792 Addressable devices system wide. To the right are general terms and their associated specific part numbers as referenced in this manual: TERM RN RT MX MX PART NUMBER PRN-4, PRN- CRT- MMX-1, MMX-101, MMX- CMX-1 or CMX- P 5 C 2 M 2 C 2 Note: The term "loop" is used in a general way throughout this document and does not necessarily mean that the circuit is a Class A configuration, unless a reference is made to Style 6, Style 7, Style D or Style Z circuit performance. Installation 15088: J 10/22/99 1-3

Fire Alarm and Related Service Standards It is imperative the installer understand the requirements of the Authority Having Jurisdiction (AHJ) and review the following documents for applicability: NFPA 72 National Fire Alarm Code NFPA 90A Air Conditioning and Ventilating Systems NFPA 92A Smoke Control Systems NFPA 92B Smoke Management Systems in Malls, Atria, Large Areas UL 916 Energy Management Systems UL1076 Proprietary Burglar Alarm Units and Systems UL 1459 Surge Suppressor Device Compatibility UL1610 Central Station Burglar Alarm Units CAN/ULC - S527 - M87 Standard for Control Units for Fire Alarm Systems EIA-232E Serial Interface Standard EIA-485 Serial Interface Standard NEC Article 300 Wiring Methods NEC Article 760 Fire Protective Signaling Systems UL 38 Manually Actuated Signaling Boxes UL 217 Smoke Detectors, Single and Multiple Station UL 228 Door Closers-Holders for Fire Protective Signaling Systems UL 268 Smoke Detectors for Fire Protective Signaling Systems UL 268A Smoke Detectors for Duct Applications UL 346 Waterflow Indicators for Fire Protective Signaling Systems UL 464 Audible Signaling Appliances UL 521 Heat Detectors for Fire Protective Signaling Systems UL 864 Standard for Control Units for Fire Protective Signaling Systems UL 1481 Power Supplies for Fire Protective Signaling Systems UL 1638 Visual Signaling Appliances CAN/ULC - S524 - M91 Standard for Installation of Fire Alarm Systems Applicable local and state building codes 1-4 Installation 15088:J 10/22/99

Section One Installation Overview Section 1.1 Basic Equipment The basic equipment package for the Notifier AM2020 is the BE-2020N and the basic equipment package for the Notifier AFP1010 is the BE-1010N. The following list may be used to identify the components provided in a BE-2020N and/or BE-1010N shipment. Refer to Appendix B of this manual for an optional equipment listing. Cables: MPS/ICA Power Cable (75378) CPU/MPS Supervisory Cable (71031) BP-3 Battery Dress Panel CPU-2020 (BE-2020N) or CPU-2 (BE-1010N) Central Processor Unit DIA-1010 or DIA-2020 Display Interface Assembly CPU to DIB Cable (75226) ICA-4L Interconnect Chassis Assemblies Refer to Section Six, Standard Specific Requirements, for minimum system equipment requirements. Section 1.2 Related Documentation To obtain a complete understanding of specific features within the AM2020/AFP1010 or to become familiar with functions in general, make use of the documentation noted in Table 1.2-1. VeriFire is a Windows 95/98 based software program which provides an off-line programming and test utility designed to reduce installation programming time. The Notifier Document chart (DOC-NOT) provides the current document revision. A copy of this document is included with each shipment of Notifier products. Installation 15088: J 10/22/99 1-5

TITLE NUMBER TITLE NUMBER AM2020/AFP1010 FIRE ALARM CONTROL PANEL 15088 ANNUNCIATOR CONTROL SYSTEM 15842 LIQUID CRYSTAL DISPLAY (LCD-80) 15037 LAMP DRIVER MODULES (LDM) 15885 NETWORK CONTROL STATION 51095 VOICE ALARM MULTIPLEX 15889 INTELLIGENT NETWORK ANNUNCIATOR (INA) 15092 THE XP SERIES TRANSPONDER SYSTEM 15888 UNIVERSAL ZONE CODER INSTALLATION (UZC-256) 15216 NETWORK ADAPTOR MODULE (NAM-232) 50038 PRODUCT INSTALLATION DOCUMENT (CCM-1) 15328 PRODUCT INSTALLATION DOCUMENT (MPS-TR) 15331 AM2020/AFP1010 OPERATOR INSTRUCTIONS 15337 THE UDACT UNIVERSAL DIGITAL ALARM COMMUNICATOR/TRANSMITTER FCPS-24/FCPS-24E FIELD CHARGER/POWER SUPPLY INSTALLATION, OPERATION AND APPLICATION MANUAL VIDEO GRAPHICS ANNUNCIATOR SYSTEM (VGAS) INSTALLATION MANUAL 50050 50059 50251 NOTIFIER DEVICE COMPATIBILITY DOCUMENT 15378 MEDIA INTERFACE BOARD (MIB) 50255 ANALOG FIRE PANEL (AFP-200) 15511 REPEATER (RPT) 50256 CANADIAN REQUIREMENTS FOR THE AM2020/AFP1010 15631 NOTI-FIRE-NET TM 50257 NETWORK INTERFACE BOARD (NIB-96) 15666 TELEPHONE/PANEL INTERFACE (TPI-232) 50372 SMOKE CONTROL MANUAL 15712 AUTOMATIC FIRE ALARM WARDEN STATION SERIES PRODUCT INSTALLATION DRAWING 50705 ANALOG FIRE PANEL (AFP-300/AFP-400) 50253/50259/ 50260 MMX-2 INSTALLATION INSTRUCTIONS M500-03-00 ACT-2 AUDIO COUPLING TRANSFORMER 51118 CHG-120 BATTERY CHARGER 50641 APS-6R AUXILIARY POWER SUPPLY 50702 XP5 SERIES TRANSPONDERS 50786 RM-1 SERIES REMOTE MICROPHONES 51138 NBG-12LX PULL STATION 51093 VEC 25/50 VOICE EVACUATION CONTROLPANEL 50686 allndocs.tbl 11/30/99 Table 1.2-1 Related Documentation 1-6 Installation 15088:J 10/22/99

General Section Two Cabinet Selection and Component Installation The cabinet assembly consists of two basic components; the backbox (SBB) and door (DR). All cabinets for the AM2020/AFP1010 are fabricated from 16-gauge steel. Cabinet parts are painted Notifier gray or red with navy blue windows. Provided with the key-locked door are a pin-type hinge, window, two keys, and the necessary hardware to mount the door to the backbox. The backbox has been engineered to provide ease-of-entry, with knockouts positioned at numerous points to simplify conduit installation. The hinges are field-selectable for either left or right mounting. The door opens 180 degrees. Product Line Information Cabinets are available in sizes A through D. The cabinets are identified by product codes CAB-A3 for the smallest enclosure through CAB-D3 for the largest. A trim ring (TR) option is available for semi-flush mounting (TR-A3, TR-B3, TR-C3, TR-D3). A wire channel (WC) option provides a pair of wire trays to neatly route wire between rows in the cabinet. Order one pair per cabinet row. Prior To Installation The doors may be mounted in either a left or right opening configuration; aiding in installation and service when two control panels are mounted in a confined area or side-by-side (as shown). In this manner the doors may be opened "barn door" style, creating an open work space. Note that in this type of installation it is necessary to leave enough space between cabinets to insert a key into the locks on the door frames. Left Mount On a left mounted door, the Display Interface Assembly (DIA) dress panel cannot be opened when the door is at less than a 120 degree angle to the cabinet. If you are using the left mounting option, be sure that the door can open at least 120 degrees. This is especially important if the cabinet is to be mounted in a closed area, such as a closet or utility room. NOTE The two hinges and the two alignment tabs should be attached to the backbox before any equipment is mounted in the backbox. See the Door Assembly Instructions section. Left Mounted Door Right Mounted Door Installation 15088: J 10/22/99 1-7

Section 2.1 Mounting the Backbox The cabinet may be either surface mounted or semi-flush mounted (refer to Figure 2.1-1). Mount the cabinet in a clean, dry, vibration-free area, using the four holes provided in the back surface of the backbox. Locate the cabinet so that the top edge is 66 inches (168 cm) above the surface of the finished floor. This procedure places the center of the control panel keypad 60 inches (152 cm) above the finished floor. Mounting Holes Figure 2.1-1 Cabinet Backbox Mount CAUTION! Unless you are familiar with the placement of components within this backbox, use only the knockout locations provided for conduit entry. Do not allow any conduit entry at the bottom of the panel where the batteries are to be mounted (see Figure 2.4-2). 1-8 Installation 15088:J 10/22/99

Door Assembly Instructions Hinges can be either left or right mounted. The illustrations and text depict a left-mount example. For right mounting, simply substitute right for left in the instructions. 1) Insert door hinges (A) into the top and bottom slots of the side to be hinged (in this case the left side). Secure the hinges to the studs in the backbox with the nuts provided. Note that the small hole on the outer tab faces outward. 2) Thread stud (B) into the BOTTOM hinge first. Thread from the bottom up. Place the grounding star washer on the stud. Place the door's lower corner onto this stud. Placing the door on the lower stud first provides a place for the door to rest while completing the assembly. 3) Align the door on the backbox, so that the door sits directly under the top hinge. Thread remaining stud (B) into the TOP hinge and through the hole in the top of the door. The door should now swing freely. Top Left Corner A Small Hole Faces Outward B Bottom Left Corner A Star Washer B Installation 15088: J 10/22/99 1-9

4. Install the door alignment tabs (C) in the unused slots on the backbox (top and bottom). (In this example the door was mounted on the left, leaving the unused slots on the right). Secure alignment tab (C) to top PEM stud with nut provided. These tabs align the door correctly with the backbox and prevent the door from being "skewed" open. Top Right Corner 5. Punch out the knockout for the door lock and install the snap-in lock mechanism by pressing it into the hole. Be sure to do this LAST, so you will be sure to knock out the correct side. C CAUTION: The lock must be installed in locked position with the key removed. The installation picture below shows the proper lock position for a left-hand mounted cabinet door. Left hinged door Install Lock Here C Bottom Right Corner Open Locked Locked Open The lock mechanism as viewed in a left-hinged mounting application. The lock would be placed in the right edge of the door. The lock mechanism as viewed in a right-hinged mounting application. The lock would be placed in the left edge of the door. 1-10 Installation 15088:J 10/22/99

Section 2.2 CAB-3 Series Backboxes CAB-A3 The CAB A-3 is the cabinet and door assembly for one mounting row. An optional TR-A3 trim ring is available for use with the A-size cabinet, which is 24.125 inches wide by 20.125 inches high (612.775 mm wide by 511.175 mm high). The following replacement parts are available: DR-A3 door SBB-A3 backbox CAB-C3 The CAB-C3 is the cabinet and door assembly for three mounting rows. An optional TR-C3 trim ring is available for use with the C-size cabinet, which is 24.125 inches wide by 37.250 inches high (612.775 mm wide by 946.15 mm high). The following replacement parts are available: DR-C3 door SBB-C3 backbox Installation 15088: J 10/22/99 1-11

CAB-B3 The CAB-B3 is the cabinet and door assembly for two mounting rows. An optional TR-B3 trim ring is available for use with the B-size cabinet, which is 24.125 inches wide by 28.625 inches high (612.775 mm wide by 727.075 mm high). The following replacement parts are available: DR-B3 door SBB-B3 backbox CAB-D3 The CAB-D3 cabinet and door assembly for four mounting rows. An optional TR-D3 trim ring is available for use with the D-size cabinet, which is 24.125 inches wide by 48.875 inches high (612.775 mm wide by 1165.225 mm high). The following replacement parts are available: DR-D3 door SBB-D3 backbox 1-12 Installation 15088:J 10/22/99

Section 2.3 Mounting the ICA-4L The AM2020/AFP1010 system may use one to three Interconnect Chassis Assemblies (ICA), depending on the specific installation requirements. The AFP1010 requires only one ICA when using LIB-400s. The ICA-4L is a low profile mounting chassis that currently replaces the ICA-4 in all BE-1010N and BE-2020N basic equipment kits. The ICA-4L is compatible with both CAB-2 and CAB-3 cabinets and the ICA-4 chassis. The ICA-4L is required when employing the LIB-400 local mode general alarm bus (refer to The Loop Interface Boards, Section 4.2 of this chapter). When using more than one ICA-4L, interconnect each ICA-4L before mounting it to the backbox by mating the male connector on one chassis to the female connector on the other (no cable is required). Align all ICA-4L Assemblies over the studs in the backbox. Connect chassis grounding cable, part number 71073 for each board to be installed on the ICA-4L to an ICA-4L stud. Secure the assemblies and cables with the nuts and washers provided. Each ICA-4L is marked with "TOP" for proper orientation. The ICA-4L is recommended when installing the SIB-2048A, SIB-NET, LIB-200A, or LIB-400 because a 16- position receptacle is mated with a 16-pin plug. The LIB-400 is used to illustrate this in Figure 2.3-1. LIB-400 Figure 2.3-1 ICA-4L 16 Position Receptacle Connections The power cable part number 75378, (refer to Figure 2.3-2) is able to mate properly with the ICA-4L since it has a 16 position receptacle. The power cable also has an 8-position receptacle to connect to the main power supply (refer to Figure 2.3-3). 59 in. (149.86 cm) - expands to fit a CAB-D3 size cabinet Figure 2.3-2 Power Cable Part Number 75378 Installation 15088: J 10/22/99 1-13

OPTIONAL Figure 2.3-3 Using the Optional Expansion Power Cable 1-14 Installation 15088:J 10/22/99

Expansion power cable part number 75379 (Figure 2.3-4), is able to mate properly with the ICA-4L since it consists of a 16-pin plug and a 16-position receptacle (Figure 2.3-3). Note: Only one power expansion cable is needed per system. OPTIONAL 36 in. (91.44 cm) - expands to fit up to a CAB-D3 size cabinet Figure 2.3-4 Expansion Power Cable Part Number 75379 Any board with a 15-position receptacle suitable for use on the ICA-4 may also be mounted on the 16-pin plug ICA-4L. The following nine boards have 15-position receptacles and may be installed on the ICA-4L: CPU-2 CPU-2020 SIB-64 SIB-232 SIB-2048 UZC-256 CCM-1 LIB-200 NIB-96 When installing any board consisting of 15-position receptacles on the 16-pin plug ICA-4L, only pins one through 15 will engage. The 16th pin will remain on the outside of the board receptacle (refer to Figure 2.3-5). A 16-position ICA-4L is required for local mode general alarm bus operation (refer to The Loop Interface Boards, Section 4.2 of this manual). Figure 2.3-5 ICA-4L 15 Position Receptacle Connections Installation 15088: J 10/22/99 1-15

Although cable part number 75142 consists of a 15-pin plug and a 15-position receptacle (Figure 2.3-6) it can still be mated on the 16-pin plug ICA-4L, only pins one through 15 will engage. The 16th pin will remain on the outside of the board receptacle (Figure 2.3-7). 36 in. (91.44 cm) - expands to fit up to a CAB-D3 size cabinet Figure 2.3-6 Cable Part Number 75142 Figure 2.3-7 Cable Part Number 75142 Connected to the ICA-4L Figure 2.3-8 illustrates the installation of a LIB-200, LIB-200A, and/or LIB-400 module in the back right position of an Interconnect Chassis Assembly (behind the CPU, which is installed later). Installation of boards in the remaining ICA-4L positions involve a similar procedure. 1-16 Installation 15088:J 10/22/99

Step 1 Place the board in front of the Interconnect Chassis Assemblies (ICA-4L) in the position where it will be installed. Tilt the board into the ICA-4L and align the square slots on the board with the first set of four tabs on the ICA-4L as illustrated. Step 2 Carefully push the board back to the first level and then slide it away from the ICA-4L, until it is directly over the second set of four tabs, now located immediately behind the printed circuit board. Step 3 Push the board back again to the second level and then slide it away from the ICA-4L until it is directly over the third set of four tabs, now located immediately behind the printed circuit board. Step 4 Now push the board back so that it is resting on the four tabs behind the board. Slide the board inward toward the center of the ICA-4L and carefully engage the female connector on the board with the male connector on the ICA-4L. When the board is correctly seated, it will be stopped by a mechanical tab. Some force is required. Before applying force, carefully check alignment of all pins. When finished, the board should be seated in a channel consisting of four retaining tabs in front of the printed circuit board and four retaining tabs behind the printed circuit board. CAUTION Remove Serial Interface Boards (SIBs) carefully, as the metal tabs on the ICA-4L may shear off some of the SIB components. NOTE For installation of system boards in the first level of the ICA-4L, omit Steps 2 and 3. Figure 2.3-8 Mount System Boards to the ICA-4L Chassis Installation 15088: J 10/22/99 1-17

Section 2.4 Component Placement Each component in the system has a specific mounting position in the cabinet. Mount any optional APS-6R power supplies and amplifiers in CHS-4/4L chassis positions A through D as required. It is recommended that the CHS-4/4L chassis always be installed in the lowest cabinet row available (refer to Table 2.4-1). CABINET MODELS CABINET ROWS CAB-A3 1 CAB-B3 2 CAB-C3 3 CAB-D3 4 Table 2.4-1 Cabinet Size Information Optional component placement guidelines are provided in Figure 2.4-1. NIB-96 (Power-limited) Mounts in any one LIB position or any two CHS-4/4L positions. UZC-256 (Power-limited) Mounts in any one LIB position or any two CHS-4/4L positions. CCM-1 (Power-limited) Mounts in any one LIB position or any two CHS-4/4L positions. NAM-232 (Power-limited) Mounts in either the left or right position of a CHS-4 by using four PEM studs on the CHS-4 chassis. Figure 2.4-1 Component Placement Guidelines 1-18 Installation 15088:J 10/22/99

Figure 2.4-2 depicts the LIB SLC numbering scheme for an AFP1010 in a CAB-B3 cabinet. If a CAB-A3 cabinet is used with LIB-400 modules exclusively, it may house a maximum four loop AFP1010 system (refer to Figure 2.4-4). One or two ICA-4L or ICA-4 chassis are required to mount the LIB modules depending upon the number and type of LIB modules employed. Refer to Figure 2.4-3 as an example of AM2020 applications. NOTE The installation of LIB modules resulting in duplicate LIB SLC numbers is never permitted. Figure 2.4-2 AFP1010 LIB SLC Numbering Scheme Installation 15088: J 10/22/99 1-19

Figure 2.4-3 depicts the LIB SLC numbering scheme for an AM2020 in a CAB-D3 cabinet. Three ICA-4L chassis are required to mount the various types of LIB modules employed. Refer to Figure 2.4-2 as an example of AFP1010 applications. NOTE The installation of LIB modules resulting in duplicate LIB SLC numbers is never permitted. Figure 2.4-3 AM2020 LIB SLC Numbering Scheme 1-20 Installation 15088:J 10/22/99

Figure 2.4-4 depicts a CAB-A3 cabinet used with LIB-400 modules exclusively, which means it may house a maximum four loop AFP1010 system. An ICA-4L or ICA-4 chassis (neither of which is shown in the figure) is required for mounting the LIB-400. Figure 2.4-4 LIB-400 Placement in an AFP1010 Figure 2.4-5 depicts the AFP1010 with a combination of LIB-400, LIB-200A, and LIB-200 modules installed in the first and second rows of a CAB-C3 cabinet. Two ICA chassis are required, but are not shown in the figure. The LIB-400 always occupies both addresses (refer to Figures 2.4-4 and 2.4-6). Various combinations of LIB boards may be installed (refer to Figure 2.4-3) as long as the following measures are taken: Do not install duplicate loop numbers. When installed in the ICA the LIB-200 or LIB-200A always occupies the lower number address for a given ICA position. Do not install LIB boards in the back right or back left positions of the second row. Do not install LIB boards in row three. Installation 15088: J 10/22/99 1-21

Loop 1 (LIB-200) SIB CPU Loop 4 (LIB-400) Loop 2 (LIB-400) Loop 3 (LIB-200 or LIB-200A installed in left front position of ICA.) CHS-4/4L A B C D MPS-24A or MPS-24AE Batteries Figure 2.4-5 LIB Placement Example in an AFP1010 1-22 Installation 15088:J 10/22/99

Figure 2.4-6 depicts a CAB-C3 cabinet used with LIB-400 modules exclusively, which means it may house a maximum ten loop AM2020 system. An ICA-4L or ICA-4 chassis (neither of which is shown in the figure) is required for mounting the LIB-400. Figure 2.4-6 LIB-400 Placement in an AM2020 Installation 15088: J 10/22/99 1-23

Figure 2.4-7 depicts the AM2020 with a combination of LIB-400, LIB-200A, and LIB-200 modules installed in the first and second rows of a CAB-C3 cabinet. Two ICA chassis are required, but are not shown in the figure. The LIB-400 always occupies both addresses (refer to Figures 2.4-4 and 2.4-6). Various combinations of LIB boards may be installed (refer to Figure 2.4-3) as long as the following measures are taken: Do not install duplicate loop numbers. When installed in the ICA the LIB-200 or LIB-200A always occupies the lower number address for a given ICA position. Loop 1(LIB-200 or LIB-200A) SIB CPU Loop 7 (LIB-400) Loop 2 (LIB-400) (LIB-400) Loop 3 Loop 5 Loop 8 Loop 10 Loop 4 (LIB-200 or LIB-200A) Loop 6 (LIB-200 or LIB-200A) CHS-4/4L A B C D MPS-24A or MPS-24AE Batteries Figure 2.4-7 LIB Placement Example in an AM2020 1-24 Installation 15088:J 10/22/99

Section 2.5 Optional Chassis Mounting When using an optional CHS-4/4L Chassis (refer to Figure 2.5-1), mount the chassis in the lowest available row in the cabinet, below previously mounted Interconnect Chassis Assemblies (ICA-4L). The CHS-4/4L is marked to identify the top of the chassis. Connect grounding wires of equipment to be placed in the CHS-4/4L to the PEM stud indicated. Secure the unit to the cabinet with the nuts and lock washers provided. NOTE The CAB-A3 Cabinet will not accept an additional chassis. CHS-4 Chassis To equipment mounted in CHS-4/4L Figure 2.5-1 Optional Chassis Mount Installation 15088: J 10/22/99 1-25

Section 2.6 Other Components Display Interface Assemblies The Display Interface Assembly (DIA) includes a backlit Liquid Crystal Display (LCD), operator keypad, the Display Interface Board (DIB), hinged dress panel, and the CPU to DIB cable. Only one DIA is required per system. The DIA-2020 is included with the BE-2020N Basic Equipment Package for the AM2020. The DIA-1010 is included with the BE-1010N Basic Equipment Package for the AFP1010. Figure 2.6-1 shows elements visible from the cabinet front. Note that the DP-1 dress panel is not included in the BE-1010N or BE2020N. BP-3 The Battery Dress Panel (BP-3) covers the Main Power Supply and the batteries in the cabinet. Only one BP-3 is required per system. DP-1 The Dress Panel (DP-1) covers additional ICA-4L or CHS-4/4L assemblies in the cabinet. Figure 2.6-1 Intelligent Fire Detection and Alarm System 1-26 Installation 15088:J 10/22/99

Section 2.7 Display Interface Connection DIA-1010 and/or DIA-2020 provide access to the system CPU and the optional SIB, and an EIA-232 unsupervised printer interface (refer to Figure 2.7-1). When terminal supervision is not required and the terminal (if present) has no keyboard, the DIA-1010 and/or DIA-2020 provide an EIA-485 interface which may be used to connect an LCD-80 (in Terminal Mode). Display Interface Assembly (DIA-1010/DIA-2020) viewed from the rear. 6 NOTE The plug-in terminal block TB1 may be removed to facilitate field wiring the LCD-80 and remote printer connections (see below). 1 TB1 J3 Display Interface Board (DIB) J4 DIB J3 TB1 Return (+) Out (+) Out (-) Return (-) All terminals are power-limited EIA-485 to LCD-80 NOTE If a supervised CRT or CRT with keyboard has been installed, this interface cannot be used. The CCM-1 Communications Converter Module must be employed to connect the LCD-80 in terminal mode. For details, refer to the LCD-80 Liquid Crystal Display Manual listed in the Related Document Chart in the front of this manual. DIB J4 Connect ribbon cable 75226 from DIB J3 to CPU P3 Connect ribbon cable 71046 from DIB J4 to SIB P4 All terminals are powerlimited TB1 Transmit to Printer EIA-232 Reference EIA-232 to Notifier PRN or Keltron Printer #VS4095/5 Outputs are power limited, but not supervised nor opto-isolated. Connections must be made with overall foil/braided-shield twisted paired cable suitable for EIA-232 and EIA-485 applications. The printer must be installed in the same room as the control panel. Terminate shield at cabinet entrance only. Plug this DB-25 connector into the EIA-232 Port of either the PRN printer or the Keltron Printer Number VS4095/5. Figure 2.7-1 Display Interface Assembly Installation 15088: J 10/22/99 1-27

Figure 2.7-2 depicts typical system cable placement. 71030 (to ICA) 71031 75226 71046 71033 71033 71072 71070 CAUTION! Be sure to allow for BP-3 Battery Dress Panel screw clearance between batteries here. NOTE The battery charger output is not powerlimited. All wiring connected to these terminals must remain at least ¼ inch (6.35 mm) from all power-limited wiring. Refer to Figure 2.7-3 for wiring information. Figure 2.7-2 Wiring Placement Diagram 1-28 Installation 15088:J 10/22/99

Figure 2.7-3 depicts a typical AM2020/AFP1010 installation and is provided as a guide for proper wiring placement. The AC and battery wiring are not power-limited. A separation of at least ¼ inch (6.35 mm) must be maintained between power-limited and nonpower-limited wiring. Install the tie wraps and adhesive squares as indicated in Figure 2.7-3. Wire Channel (Model WC-2) Adhesive square and tie-wrap on back of cabinet affixing power-limited wiring. Adhesive square and tie-wrap on top of power supply chassis affixing nonpower-limited wiring. Figure 2.7-3 Power-Limited and Non Power-Limited Wiring Figure 2.7-4 is provided as a guide for dress panel placement. Installation 15088: J 10/22/99 1-29

DIA-1010 or DIA-2020 DP-1 Dress Panel DP-1 Dress Panel BP-3 Battery Dress Panel Figure 2.7-4 Dress Panel Placement Diagram 1-30 Installation 15088:J 10/22/99

Section 2.8 Mounting the MOD-1 Module Plate The MOD-1 allows a single MMX-1, MMX-2 or CMX module to mount in a CAB-3. It occupies one of the four positions available in a row on the CHS-4 or CHS-4L Chassis. The following five steps describe how to mount the MOD-1 in a chassis, and Figure 2.8-1 illustrates the five steps of this installation. 1. Firmly press the module to be installed into the square opening on the MOD-1 until it snaps into place. 2. Secure the module to the MOD-1 with the two screws provided. Make connections to the module at this time. 3. Angle the bottom edge of the MOD-1 into the slot on the bottom of a chassis position. Swing the MOD-1 assembly into the chassis. 4. Secure the assembly to the chassis by tightening the captive screws on the MOD-1. 5. To install the CHS-4L chassis, follow Steps 1 and 2 above. After completing Step 2, screw the two standoffs provided to the upper studs of a CHS-4L chassis position as shown in Step 5 of Figure 2.8-1. Then continue on with Steps 3 and 4. Installation 15088: J 10/22/99 1-31

MOD1Inst. Figure 2.8-1 Mounting the MOD-1 into the CHS-4 and CHS-4L Chassis 1-32 Installation 15088:J 10/22/99

Section Three Power Supplies Section 3.1 The AC Primary Power Input The AM2020/AFP1010 requires primary AC power. Connection to the light and power service must be on a dedicated branch circuit and the wiring for this circuit must be installed in conduit. The switch for this circuit must be labeled "Fire Alarm Circuit Control". Access to the switch must be limited to authorized personnel and the location of the switch must be identified inside of the AM2020/AFP1010 cabinet door. No other equipment may be powered from the fire alarm circuit. The AC circuit wire run must run continuously, without disconnect devices, from the power source to the Fire Alarm Control Panel (FACP). Overcurrent protection for this circuit must comply with Article 760 of the National Electrical Code (NEC) as well as local codes. Use 12 AWG (3.25 mm²) wire with 600 volt insulation for this circuit. Use Tables 3.1-1 and 3.1-2 to calculate the total amount of current, in amps, that the AC service must be capable of supplying to the system. Device Type # of Devices Multiply by Current in Amps A PS-6R X 2. 5 A A-30 X 1. 0 A A-100/AA-120 X 1.85 Main Power Supply (MPS-24A) Table 3.1-1 120 VAC Fire Alarm Circuit Total Current [ 1 ] X 1. 8 1. 8 S um Column for AC Branch Current Required = Amps Device Type # of Devices Multiply by Current in Amps A PS-6R X 1. 2 A A-30E X 0. 5 A A-100E/AA-120E X 0. 9 Main Power Supply (MPS-24AE) Sum Column Table 3.1-2 220/240 VAC Fire Alarm Circuit Total Current [ 1 ] X 0. 9 0. 9 for AC Branch Current Required = Amps Section 3.2 The MPS-24A or MPS-24AE Main Power Supply The Main Power Supply (MPS-24A or MPS-24AE) provides up to 3.0 amps of filtered current for operating the system in standby (non-fire alarm) and up to 6.0 amps during fire alarms. The MPS-24A or MPS-24AE contains battery charging circuitry and a 1-amp filtered output for powering 4-wire smoke detectors. Each MPS-24A or MPS-24AE also provides filtered, non-resettable 24V DC required for powering ACS Annunciator modules. If a voltmeter and ammeter are required on the MPS-24A or MPS-24AE, order the MPM-2 Main Power Meter. Note: The battery charging circuitry on the MPS-24A can only operate under the control of the CPU-1010/2020, an XPP-1, or an MPS-TR. Without one of these controlling devices, the batteries will not be charged. Installation 15088: J 10/22/99 1-33

The MPS-24A or MPS-24AE Main Power Supply must be capable of powering all internal system devices (and several external types of devices) continuously during non-fire alarm conditions. Use Table 3.2-1 to determine the non-fire alarm load on the MPS-24A or MPS-24AE output when primary power is applied. A finite amount of additional current must be provided by the power supply during a fire alarm condition. For the MPS-24A or MPS- 24AE, use Table 3.2-2 to determine the additional current needed during fire alarms. The requirements for nonfire alarm and fire alarm current loads cannot exceed the capabilities of the power supply in either case. The following paragraphs provide additional information to the AM2020/AFP1010 System Current Draw Calculation Table (Table 3.2-1). In the AM2020/AFP1010 System Current Draw Calculation Table (Table 3.2-1) the primary power non-fire alarm current and the primary fire alarm current columns are not battery calculations. They are simply current calculations to confirm that the MPS-24A can output enough DC current to support the AM2020/ AFP1010 system during non-fire alarm and fire alarm conditions when operating from primary power. The word "primary" refers to the FACP's primary source of power, i.e. 120 VAC or 220/240 VAC power. The word "secondary" refers to the FACP's backup batteries (or any other 24 VDC uninterruptable, filtered power supply listed for Fire Protective Signaling and connected in place of the batteries). Specific columns within Table 3.2-1 are further defined as follows: Primary, Non-Fire Alarm Current (amps) This column allows the user to calculate the current that will be drawn from the MPS-24A or MPS-24AE during a non-fire alarm condition, with AC power applied. This current draw cannot exceed 3.0 Amps. Primary, Fire Alarm Current (amps) Secondary, Non-Fire Alarm Current (amps) This column allows the system designer to determine the output current load that must be supported by the Main Power Supply MPS-24A or MPS-24AE during a fire alarm condition with primary power applied. The total current drawn from the MPS-24A or MPS-24AE during a fire alarm condition cannot exceed 6.0 amps. The last column of Table 3.2-1 allows the system designer to calculate the secondary non-fire alarm current. This is the current that will be drawn from the MPS-24A or MPS- 24AE power supply in a non-fire alarm condition during AC power loss. This figure is required to complete the standby battery calculations. After adding up all the individual current draws, the total current draw figure is then transferred to Table 3.2-3. NOTES Typically, a system should be designed around the capacity to activate all output circuits and relays, and support fire alarms on no less than 10 percent of initiating device circuits (subject to the requirements of the Local Authority Having Jurisdiction (LAHJ). Concerning 4-wire detectors: In Table 3.2-1, the current to be entered for 4-wire smoke detectors is the manufacturer's rated fire alarm current minus the manufacturer's rated non-fire alarm current. Concerning notification appliances: The MPS-24A or MPS-24AE provides a filtered supply for notification appliance circuits, and is UL Listed as a Special Application power supply. Therefore, only notification appliances listed in the Notifier Device Compatibility Document (15378) should be used with this power supply. (Note: This restriction also applies to the APS- 6R and FCPS-24 power supplies). Enter into Table 3.2-1 the respective current draws of notification appliances and other external devices to be powered by the MPS-24A or MPS-24AE during a fire alarm. Do not add devices to be powered by an auxiliary power supply. No more than 3.0 amps of current can be drawn from Terminals 3 and 4 of TB3. Security Alarms are treated as trouble (non-fire alarm) conditions in the AM2020/AFP1010. 1-34 Installation 15088:J 10/22/99

CATEGORY COLUMN A PRIMARY, NON-FIRE ALARM CURRENT (AMPS) (MPS-24A OR MPS-24E OUTPUT CURRENT REQUIRED WHEN OPERATING FROM PRIMARY POWER COLUMN B PRIMARY, FIRE ALARM CURRENT (AMPS) COLUMN C SECONDARY, NON-FIRE ALARM CURRENT (AMPS) BE-2020N or BE-1010N (CPU, DIA, & 1 ICA-4L) MPS-24A MPM-2 QTY X [CURRENT DRAW]= TOTAL QTY X [CURRENT DRAW]= TOTAL QTY X [CURRENT DRAW]= 1 x [0.162] = 0.162 1 x [0.162]= 0.162 1 x [0.118] = 0.118 1 x [0.064]= x [0.006]= 0.064 1 x [0.064]= x [0.006]= 0.064 1 x [0.104]= x [0.006]= ICA-4L x [0.002]= x [0.002]= x [0.002]= LIB-200 (10 max.) x [0.078]= x [0.100]= x [0.049]= LIB-200A (10 max.) x [0.085]= x [0.085]= x [0.085]= LIB-400 (5 max.) x [0.170]= x [0.170]= x [0.170]= SIB-232 SIB-2048A SIB-NET MIB-W MIB-F MIB-WF x [0.050]= x [0.060]= x [0.070]= x [0.035]= x [0.028]= x [0.033]= x [0.050]= x [0.060]= x [0.070]= x [0.035]= x [0.028]= x [0.033]= x [0.045]= x [0.055]= x [0.070]= x [0.035]= x [0.028]= x [0.033]= INA x [0.250]= x [0.250]= x [0.250]= RPT-W RPT-WF RPT-F RPT-485W/RPT-485WF SDX, CPX & FDX-551, SDX-551TH, MMX-1 IPX-751 MMX-101,CMX-1,BGX-101L CMX-2, NBG-12LX MMX-2 - See MMX-2 Instructions B601BH B501BH (Horn in Base) DHX-501,DHX-502 See instructions ISO-X 4-Wire Smoke Detectors See Device Compatibility Document x [0.031]= x [0.033]= x [0.028]= x [0.017]= x [0.00020]= x [0.00035]= x [0.00030]= x [0.00030]= x = x [0.00100]= x [0.00100]= x = x [0.00045]= x = x = x [0.031]= x [0.033]= x [0.028]= x [0.017]= x [0.00020]= x [0.00045]= x [0.00043]= x [0.00030]= x = x [0.00100]= x [0.01500]= x = x [0.00045]= x = x = x [0.031]= x [0.033]= x [0.028]= x [0.017]= x [0.00020]= x [0.00035]= x [0.00030]= x [0.00030]= x = x [0.00100]= x [0.00100]= x = x [0.00045]= x = x = RM-1/RM-1SA x [0.020]= x (0.066]= x [0.020]= AMG-1, AMG-E, ATG-2 FFT-7, FFT-7S AA-30/AA-30E AA-30 w/ ACT-2 See Document 51118 AA-100/AA-100E, AA-120/AA-120E APS-6R ACM-16AT, ACM-32A AEM-16AT, AEM-32A LCD-80 ACM-8R (see Doc.15342) LDM Series (see Doc.15885) SCS Series (see Doc.15712) Number of annunciator LEDs illuminated during non-fire alarm conditions: ACM-16AT, AEM-16AT, ACM-32A, AEM-32A XPP-1 XPM-8 (8 zones) XPM-8 (4 zones) XPM-8L (8 zones) XPC-8 (8 circuits) XPC-8 (4 circuits) XPR-8 SUM EACH COLUMN FOR SUBTOTALS, THEN ENTER IN "SUBTOTALS FROM PREVIOUS PAGE" ROW ON NEXT PAGE x [0.060]= x [0.060]= NOT APPLICABLE x[0.040]= x[0.002]= x[0.100]= x= x= x= x[0.016]= x[0.016]= x[0.023]= x[0.147]= x[0.086]= x[0.085]= x[0.033]= x[0.017]= x[0.004]= PRIMARY, NON- ALARM SUBTOTAL: x [0.060]= x [0.120]= NOT APPLICABLE x[0.056]= x[0.018]= x[0.100]= x= x= x= INCLUDED ABOVE x[0.032]= x[0.169]= x[0.108]= x[0.115]= x[0.042]= x[0.026]= x[0.013]= PRIMARY, ALARM SUBTOTAL: x [0.060]= x [0.060]= x[0.045]= x[0.050]= x[0.025]= x[0.040]= x[0.002]= x[0.050]= x= x= x= x[0.016]= x[0.016]= x[0.025]= x[0.147]= x[0.086]= x[0.085]= x[0.033]= x[0.017]= x[0.004]= SECONDARY, NON- FIRE ALARM SUBTOTAL: TOTAL 0.104 Table 3.2-1 AM2020/AFP1010 System Current Draw Calculations (1 of 2) Installation 15088: J 10/22/99 1-35

CATEGORY COLUMN A PRIMARY, NON-FIRE ALARM CURRENT (AMPS) (MPS-24A OR MPS-24E OUTPUT CURRENT REQUIRED WHEN OPERATING FROM PRIMARY POWER COLUMN B PRIMARY, FIRE ALARM CURRENT (AMPS) COLUMN C SECONDARY, NON-FIRE ALARM CURRENT (AMPS) QTY X [CURRENT DRAW]= TOTAL QTY X [CURRENT DRAW]= TOTAL QTY X [CURRENT DRAW]= TOTAL XP5 Series Transponders XP5-M XP5-C Relay XP5-C NAC/telephone x[0.001651]= x[0.000840]= x[0.001481]= x[0.003000]= x[0.000840]= x[0.001481]= x[0.001651]= x[0.000840]= x[0.001481]= Miscellaneous CCM-1 A77-716B RA-400Z(when on) NIB-96 MBT-1 UZC-256 UDACT n/a x[0.107]= x[0.020]= x[0.006]= x[0.022]= n/a x[0.035]= x[0.100]= x[0.107]= x[0.020]= x[0.006]= x[0.022]= x[0.017]= x[0.090]= x[0.100]= n/a x[0.107]= x[0.020]= x[0.006]= x[0.022]= n/a x[0.035]= x[0.100]= Notification Appliances 1 NOT APPLICABLE x= x= NOT APPLICABLE Other devices drawing power from MPS-24A terminals TB3-3 and TB3-4 x= x= x= x= x= x= SUBTOTALS FROM THIS PAGE PRIMARY, NON-ALARM SUBTOTAL: PRIMARY, ALARM SUBTOTAL: SECONDARY, NON-FIRE ALARM SUBTOTOTAL: SUBTOTALS FROM PREVIOUS PAGE PRIMARY, NON-ALARM SUBTOTAL: PRIMARY, ALARM SUBTOTAL: SECONDARY, NON-FIRE ALARM SUBTOTOTAL: SUM SUBTOTALS FROM EACH PAGE FOR TOTALS PRIMARY, NON-ALARM TOTAL: CANNOT EXCEED 3.0 A PRIMARY, ALARM TOTAL: CANNOT EXCEED 6.0 A SECONDARY, NON-FIRE ALARM TOTAL: PLACE THIS TOTAL IN TABLE 3.2-3 TO DETERMINE A.H. REQUIREMENT 1 INCLUDE ONLY THOSE DEVICES TO BE POWERED BY THE MAIN POWER SUPPLY, NOT AN AUXILIARY SUPPLY SUCH AS THE AVPS-24 OR APS-6R. SEE MANUFACTURER'S INSTRUCTIONS FOR APPLICABLE POWER DRAWS. Table 3.2-1 AM2020/AFP1010 System Current Draw Calculations (2 of 2) 1-36 Installation 15088:J 10/22/99

Maximum Secondary Power Fire Alarm Current Draw Use Table 3.2-2 to determine the maximum current requirements of the secondary power source during fire alarm conditions. The total obtained in Table 3.2-2 is the amount of current that the batteries must be capable of supplying. This figure will be used in Table 3.2-3 to determine the size of the batteries needed to support five minutes of fire alarm operation. It is presumed, in a fire alarm condition, that the batteries must feed the main power supply and any additional supplies (APS-6R, AA-30, AA-30E, AA-100, AA-100E, AA-120, and AA-120E) with the maximum rated power each supply can provide (Table 3.2-2). NOTE Due to the maximum rating of 9 amps imposed when using PS-12250 batteries, it may be necessary to calculate the exact requirements of the secondary supply. In that case, add the secondary non-fire alarm load obtained in Table 3.2-1 to the total fire alarm current draw of all notification appliances in the system and substitute that figure in Table 3.2-2 for the MPS and any APS-6Rs. Device Type # in Alarm (simultaneously) Multiply by Current in Amps Total Current Main Power Supply (MPS-24A or MPS-24AE) 1 X 6. 0 6. 0 A PS-6R X 6. 0 A A-30 or AA-30E X 3. 0 AA-100 or AA-100E AA-120 or AA-120E X 7. 3 Sum Column for Secondary Fire Alarm Load * = Amps * The secondary fire alarm load cannot exceed 9.0 amps with PS-12250 batteries, and 20 amps with PS-12600 batteries. Table 3.2-2 Maximum Secondary Power Fire Alarm Current Draw LOAD TOTALS MULTIPLIED BY TIME EQUALS SECONDARY AMP HOUR TOTALS Enter Secondary Nonfire Alarm Load from Column C of Table 3.2-1 X Enter Required Secondary Non-fire Alarm Standby Time (24 or 60 hours) = Non-fire Alarm Secondary Standby Amp Hours Enter Secondary Fire Alarm Load from Table 3.2-2 X Enter Required Fire Alarm Time (for 5 minutes, enter 0.084) for 15 minutes, enter 0.25) = Secondary Fire Alarm Amp Hour Requirement Sum column for Total Secondary Ampere Hours (AH) Calculated = Multiply by the derating factor x 1.2 = Total Secondary Ampere Hours Required = Table 3.2-3 Secondary Power Standby and Fire Alarm Load Installation 15088: J 10/22/99 1-37

Table 3.2-3 sums the non-fire alarm and alarm loads to arrive at the battery size, in Ampere Hours (AH), required to support the AM2020/AFP1010. The MPS-24A or MPS-24AE can charge batteries up to 60 AH in size. Select batteries from Table 3.2-4 that meet or exceed the total AH calculated : Battery Size Voltage Rating Number Required Model Number 9.5 AH 6 volts Four PS-695 12 AH 12 volts Two PS-12120 Cabinet Size CAB-A3, B3, C3, D3 (AFP1010 Only) CAB-A3, B3, C3, D3 (AFP1010 Only) 25 AH 12 volts Two PS-12250 CAB-A3, B3, C3, D3 60 AH 12 volts Two PS-12600 BB-55 Cabinet (Batteries Only) Table 3.2-4 Battery Size Requirements NOTE NFPA 72 Local and Proprietary Fire Alarm Systems require 24 hours of secondary non-fire alarm power followed by five minutes in alarm. NFPA 72 Auxiliary and Remote Station Fire Alarm Systems require 60 hours of secondary non-fire alarm power followed by five minutes in alarm. NFPA 72 Voice Evacuation Systems require 15 minutes of alarm time. Battery Testing You may need to test the standby batteries occasionally. Here are two testing procedures you can use to determine the charge condition and capacity of the batteries in the system. Quick Test - The quick test is a measure of charge condition; it is not a battery capacity test. Use it to identify the need to charge or replace the battery before it fails. If the battery has been part of an existing system, test results may indicate a faulty battery or a problem in the charging system. Follow this procedure: 1. Remove the fully charged battery from the sytem or charging network. 2. Place a load resistor across the terminals that limits the current flow to approximately one amp. For example, use a 12 ohm resistor with a minimum of 12 watts for a single 12 volt battery. If you have two 12 volt batteries connected in series, use a 24 ohm resistor with a minimum of 24 watts. 3. After 15 minutes, measure the voltage across the battery terminals with the resistor still in place. Be sure to use a digital meter. For a 12 volt battery, the meter reading should range between 13.8 to 12.0 VDC. For a 24 volt battery system, the range is 27.6 to 24 VDC. NOTE If the readings fall below these ranges, perform the 20-Hour Discharge Test, or replace the battery. 20-Hour Discharge Test - The 20-hour discharge test indicates the battery capacity at its amp hour rating. The advertised amp hour battery rating is based on a 20-hour discharge rate, which is the amount of current it delivers to a load for 20 hours while maintaining its terminal voltage above the levels described in Step 3 of this test. Follow this procedure: 1. Calculate the load resistor. a. Divide the amp hour rating by 20 hours. For the PS-12250 battery, the calculation would be 25/50=1.25 amps. b. We need 1.25 amps for 20 hours. Using Ohm's Law, R=E/I, therefore, R=12/1.25, or 9.6 ohms. P= I x E, so P=1.25 x 12, or 15 watts. Therefore we need a load resistor of 9.6 ohms at 15 watts. 1-38 Installation 15088:J 10/22/99

2. Measure time of load. a. Take a fully charged battery and install the load resistor across the terminals. b. Measure the voltage across the battery for a period of 20 hours. If during the test the terminal voltage drops below the minimum acceptable levels (10.2 VDC for a 12 volt battery and 20.4 VDC for a 24 volt battery), note the number of hours that have elapsed when the battery voltage drops below its minimum operational level. 3. Calculate the battery capacity. CAPACITY = TIME x LOAD where: TIME (in hours) is equal to the measured duration the terminal voltage remained at the acceptable level and LOAD is equal to the load current value. If the battery maintained its voltage level above its minimum operational level for 15 hours, its capacity would be: 15 x 1.25, or 18.75 amp hours. Conclusion: The battery has only 18.75 amp hour capacity instead of its rated 25 amp hours. Figure 3.2-1 depicts the two-step procedure of mounting the main power supply. Step 1 Position the Main Power Supply over the support bracket in the lower left corner of the cabinet and carefully push the supply down until it engages the bracket securely. Step 2 Secure the Main Power Supply to the cabinet with the two self-tapping screws provided. Figure 3.2-1 Mount the Main Power Supply Installation 15088: J 10/22/99 1-39

Test of Ground Fault Detection Circuit If you have a persistent ground fault and suspect the MPS-24A ground fault detection circuit may be generating a false indication, use this test: 1. Remove the upper right circuit board mounting screw, just to the right of P2. 2. Insert an insulator (a piece of paper will do) between the power supply circuit board and the mounting standoff. If the ground fault indication remains, the problem is with the MPS-24A. Monitoring Remote Power Supplies The MPS-24A depends on the CPU-1010/2020 or the XPP-1 to control its battery charging circuit and to monitor the battery state approximately every four minutes. If you use the MPS-24A in a remote application from the main control panel or a transponder, add the MPS-TR to the power supply to prevent problems keeping the batteries charged. The MPS-TR has a trouble relay that should be monitored by a system monitoring device. Note that the CPU or the XPP-1 can control only one power supply. Section 3.2.1 The MPS-TR Main Power Supply Monitor The MPS-TR power supply monitor mounts on any of the MPS series power supplies. This add-on board mounts on the right side of the MPS series supply and it is fastened through the use of two extended length standoffs, making use of threads on the existing standoffs (Figure 3.2-1). The MPS-TR monitor provides supervision for remote power supplies and control of the power supply battery charger when there is no CPU-1010/2020 or XPP-1 to provide these two functions. The board is mounted and secured as described above. P1 on the MPS-TR is connected to P3 on the power supply via a power ribbon cable(part number 71085) supplied with the MPS-TR. The relay common and normally closed contacts of the MPS-TR are connected to a normally closed TROUBLE INPUT on the control panel trouble monitoring circuit. MPS-TR Installation 1. Remove the upper and lower screws on the right side of the power supply main board. 2. The MPS-TR mounts on these two holes. Thread the new longer screws and the standoff sleeves into the holes formerly occupied by the two screws removed in Step 1. Figure 3.2.1-1 Threading the New Screws 1-40 Installation 15088:J 10/22/99

Figure 3.2.1-2 Mounting the MPS-TR System Common Terminal Connection MPS-24A TB3-4 MPS-24B TB2-4 Figure 3.2.1-3 System Common Terminal Connection NOTE: Relay contacts are specified in the NORMAL (no trouble condition) state. The MPS-TR connects to any device with a trouble IN and a trouble OUT connector/terminal. Installation 15088: J 10/22/99 1-41

Section 3.3 Connecting the Main Power Supply Table 3.3-1 provides the maximum output capacity of the MPS-24A or MPS-24AE main power supply. Figure 3.3-1 illustrates connections for primary and secondary power to the MPS-24A or MPS-24AE, as well as terminal and harness connections for the control panel. Connecting Primary AC Power With the circuit breaker at the main AC power distribution panel turned off, remove the plastic insulating cover from Terminal Block TB1 on the MPS-24A and connect the system primary power source. Connect the electrical system earth ground to TB1 Terminal 2 and ground the power supply assembly to the cabinet with a Chassis Ground cable (part number 71073) to TB1 Terminal 3. Connect the primary Neutral line to TB1 Terminal 4 and the primary Hot line (120 VAC for the MPS-24A or 220/240 VAC for the MPS-24AE) to TB1 Terminal 6. Do not route AC wiring in the same conduit with circuits in this control panel. After completion of these connections, reinstall the plastic insulating cover over the terminal strip. Leave the main circuit breaker off until installation of the entire system is complete. Connecting the Secondary 24V Power Source Secondary power (usually battery) is required to support the system during loss of primary power. The batteries may reside in the control panel cabinet, or in a separate BB-55 cabinet. When using a 24 VDC filtered power source other than batteries, this source must be of sufficient capacity and be listed for this purpose. Connect the Battery Positive Cable (part number 71071) to TB2 Terminal 1(+) and the Battery Negative Cable (part number 71072) to TB2 Terminal 2(-). Do not connect the Battery Interconnect Cable (part number 71070) at this time. This connection will be made just prior to initial system power-up. NOTE A separate cabinet may be required to house NiCad batteries due to battery size. Earth Ground Fault Detection The MPS-24A or MPS-24AE automatically detects ground faults in the system. To disable ground fault detection, cut Resistor R27 (refer to Figure 3.3-1). 24V DC Four-Wire Smoke Detector Power Up to one amp of power for four-wire smoke detectors can be drawn from TB3 Terminals 1(+) and 2(-). Power is removed from these terminals during system reset. This 24V DC filtered source is power-limited but must be supervised via an end-of-line Power Supervision Relay (refer to Figures 4.6-5 and 4.6-6). 24V DC Notification Appliance Power Up to 3 amps of filtered current for powering notification appliances can be drawn from TB3 Terminals 3(+) and 4(-). Power is not removed from these terminals during system reset. If additional 4-wire smoke detector power is required, this circuit can be converted to a two-amp resettable circuit by cutting JP5 on the MPS-24A or MPS-24AE (refer to Figure 3.3-1). This 24V DC power is power-limited but must be supervised via an end-of-line Power Supervision Relay. Note: This power supply is UL listed as a Special Application Power Supply. Therefore, only notification appliances listed in the Device Compatibility Document (15378) should be used with this power supply. (This restriction also applies to the APS-6R and FCPS-24 power supply.) System Harness Connections The Power Harness (part number 71030) provides internal power for circuit boards installed in the ICA-4L. Connect this harness from P2 or P4 on the MPS-24A or MPS-24AE to Plug A on the uppermost ICA-4L. The AM2020/AFP1010 monitor the power supply through connection of a Power Supply Supervision Cable (part number 71031) between MPS-24A or MPS-24AE Connector P3 and Connector P2 on the CPU (refer to Figure 3.6-1). If the MPS-24A or MPS-24AE is being used as a remote power supply, this ribbon cable should be plugged into the MPS-TR module. The MPS-TR provides a Form-C trouble contact that can be monitored by a monitor module with an "MTRB" Type ID. For connection of an MPS-TR, refer to the MPS-TR Product Installation Document listed in the Related Documentation Chart in the beginning of this manual. 1-42 Installation 15088:J 10/22/99

NVRAMS User programming information and critical operating parameters of the AM2020/AFP1010 system are stored in Nonvolatile Random Access Memory (NVRAM). Improper cycling of power to the AM2020/AFP1010 can cause the NVRAMS to become inaccessible. The AM2020/AFP1010 software now verifies the state of the NVRAMs. If a NVRAM problem has been detected, the AM2020/AFP1010 will display one of the following two error messages depending on where the problem is located: TROUBL CATASTROPHIC CPU NONVOLATILE RAM FAILURE or TROUBL CATASTROPHIC DIA NONVOLATILE RAM FAILURE Other indicators of NVRAM problems by board are: Board Trouble Message Displayed Local Board Indicator SIB-NET TROUBL CATASTROPHIC ISIB COMMUNICATIONS FAULT ATXD LED blinking at 2 second rate. The correct power down procedure is to remove battery power, then disconnect primary power (AC) at the circuit breaker in the electrical distribution panel, then wait at least one minute before disconnecting or connecting any cables or circuit boards, or reapplying primary power. The correct power up procedure is to connect primary power, then connect the battery, and wait one minute before taking any further actions, especially pressing the acknowledge button, which can cause NVRAM problems if pressed during the first minute after power application. If this condition occurs, call the factory for immediate assistance. Condition Non-Fire Alarm with Battery Charger Enabled Non-Fire Alarm with Battery Charger Disabled (See Note 2) Maximum Circuit Load (Per Circuit) 3.0 amps Total of power in columns to the left cannot exceed: Circuit Type (See Note 1) Internal 1.0 amp External 1 3.0 amps 3.0 amps nonresettable 2.0 amps resettable 3.0 amps External 2 Internal 1.0 amp 6.0 amps External 1 3.0 amps nonresettable 2.0 amps resettable 1.0 amps External 2 Internal Description While the power supply can deliver 6 amps, 3 amps of the power supply capacity are reserved for the battery charger when enabled. The remaining 3 amp capacity can be shared between the internal and external circuits during a non- fire alarm condition. When the Internal MPS-24A/E battery charger is not used, the full 6 amp capacity of the power supply can be shared between the internal and external circuits for up to one hour (4 amps continuously). During a fire alarm condition, the battery charger is automatically disabled which makes the full 6 amp capacity of the power supply available to be shared between the internal and external output circuits for up to one hour (4 amps continuously). Fire Alarm 6.0 amps 3.0 amps External 1 3.0 amps nonresettable 2.0 amps resettable External 2 Notes: 1 Internal External 1 External 2 This power is used for all internal requirements modules, boards, etc. Power Harness from MPS-24A/E P2 or P4, to the CPU. Connection: Provides resettable power to 4-wire smoke detectors (and power supervision relays). Connection: TB3 Terminals 1 (+) and 2 (-). Power for devices (typically notification appliances) listed in the Notifier Device Compatibility Document (15378). Connection: TB3 Terminal 3 (+) and 4 (-). 2 Remote Battery Charger JP1 must be cut to install a CHG-120 remote battery charger and disable the MPS- 24A/E internal charger. Table 3.3-1 MPS-24A or MPS-24AE Main Power Supply Loads Filtered Supply Installation 15088: J 10/22/99 1-43

Secondary Power 27.6 V DC, supervised and power-limited. Fast charge = 2 amps, trickle charge = 20 ma. Battery - Battery + Power Supply MPS-24A (maximum) PRIMARY POWER AC Neutral Out Neutral In Earth Ground Connect to chassis via a Grounding Cable Assembly. HZ amps 120V 50/60 1. 8 MPS-24AE ( ma ximum) 220/240V 50/60 0. 9 Hot In Hot Out Four-Wire Smoke Detector Power 24V DC ( 200 mv ripple), 1 amp maximum. Filtered and resettable. Power-limited but must be supervised via a Power Supervision Relay. + - + - Notification Appliance/ Annunciator Power Power-limited, filtered, non-resettable, 3 amps (in alarm) maximum. JP5 may be cut to convert this notification appliance power (TB3 Terminals 3 and 4) to a resettable, 2-amp maximum circuit. This output can also be used to power ACS series annunciators (do not cut JP5). Power Ribbon Connector Connect to P2 on the CPU-2020 or CPU-2 Power Harnesses (P2, P4) Connect to Plug A on the top of the ICA-4/ ICA-4L (3 amps maximum, P2 and P4 combined) or any other module or board requiring internal power. Battery Fuse (10A, 3AG) Not used with the AM2020/AFP1010. Make no connection here. Cut R27 to disable Earth Ground Fault Detection. LED Indicators Earth Ground Fault Battery Fail AC Power Fail NiCad High Charge Rate JP5: Cut to make notification appliance power on TB3 Terminals 3 and 4 a resettable 2-amp maximum circuit. JP1: When employing a CHG-120, Remote Battery Charger JP1 must be cut. MPM-2 Voltmeter/Ammeter Connector Figure 3.3-1 Field Wiring the MPS-24A or MPS-24AE Power Supply 3 amps maximum non-fire alarm load. 6 amps maximum fire alarm load. For additional ratings, refer to Appendix A. JP2: must be cut otherwise a short on the notification appliance power circuit (Terminals 3 and 4) would register incorrectly as a loss of primary (AC) power. 1-44 Installation 15088:J 10/22/99

Section 3.4 The Optional Main Power Meter The optional Main Power Meter (MPM-2) may only be installed on the Main Power Supply, MPS-24A or MPS-24AE (refer to Figure 3.4-1). Step 1 Remove the two screws in the bottom left corner of the MPS-24A or MPS- 24AE. Step 2 Thread the two replacement screws through the MPM-2 bracket and through the two standoffs provided. Place the MPM-2 assembly over the MPS-24A or MPS-24AE and secure with the two screws. Step 3 Complete the installation of the MPM-2 by plugging the female connector on the meter into Plug P7 on the MPS-24A or MPS-24AE. Figure 3.4-1 Installation of the Main Power Meter Installation 15088: J 10/22/99 1-45

Section 3.5 The CHG-120 Remote Battery Charger The Notifier Remote Battery Charger, CHG-120 is capable of charging 25 to 120 ampere hour batteries. This unit is required if the MPS-24A must deliver more than 3 amps of current when no fire alarm signal is present. Batteries up to 120 AH can be housed with the charger in the BB-55 cabinet: Batteries up to 25 AH can be housed with the charger in cabinets CAB-A3, -B3, -C3, or -D3. Refer to Figure 3.5-1 for installation positions. The charger can be mounted up to 20 feet (6.096 meters) away from the control panel. To determine the battery size needed in a particular system, refer to the Non-Fire Alarm Power Requirements. 3.5-1a 3.5-1b Figure 3.5-1 CHG-120 Installation into CAB-3 Series(3.5-1a) and BB-55 (3.5-1b) Cabinets Connecting the Primary Power Source With the circuit breaker at the main AC power distribution panel turned off, connect the primary power source to the corresponding terminal on TB1 of the CHG-120. All connections between the AM2020/AFP1010 and the CHG-120 must be made in conduit, using 12 AWG (3.25 mm²) wire. Do not route AC wiring in the same conduit as other control panel circuits. Leave the main circuit breaker off until installation of the entire system is complete. Refer to Figure 3.5-2. Connecting the Secondary Power Source Do not apply AC power or batteries until the system is completely wired and ready for testing. Refer to Wiring Diagram and Instructions for the CHG-120 Charger in the CHG-120 Charger Manual (Document 50641) for additional information. 1-46 Installation 15088:J 10/22/99

Figure 3.5-2 CHG-120 Connections Section 3.6 The APS-6R Auxiliary Power Supply The APS-6R Auxiliary Power Supply is designed to power devices that require filtered, non-resettable power such as XP Transponder modules, Notification Appliance Circuit modules, and Control modules. It provides two 24 VDC (filtered) output circuits (3 A each, 6 A total, 4 A continuous). For more information on the APS-6R, refer to the APS-6R Manual (Document 50702) Mounting an APS-6R in a CAB-3 Series Cabinet An APS-6R can mount to a CHS-4 (Figure 3.6-1a) or a CHS-4L (Figure 3.6-1b) for use in a CAB-3 Series cabinet (CAB-A3, CAB-B3, CAB-C3, or CAB-D3). To mount the APS-6R, follow these instructions: Place the APS-6R onto the mounting studs of the CHS-4 or CHS-4L chassis. Insert a standoff through each of the APS-6R mounting slots; then thread each standoff to the mounting stud on the chassis. Tighten the standoffs until the APS-6R is securely fastened to the chassis. Mount the CHS-4 or CHS-4L to the cabinet backbox. Install the APS-6R plastic cover and press-fit terminal block cover over TB1 AC connections. (Refer to Figure 3.6-2) Installation 15088: J 10/22/99 1-47

3.6-1a Figure 3.6-1 Mounting the APS-6R to a Chassis Field Wiring an APS-6R Figure 3.6-3 shows typical field wiring for an APS-6R WARNING: Use extreme caution when working with the APS-6R - high voltage and AC line-connected circuits are present in the APS-6R. Turn off and remove all power sources. To reduce the risk of electric shock make sure to properly ground the APS-6R. 3.6-1b J1 and J2 may be used in place of TB2 when the APS-6R is powering internal modules (such as the UZC-256, XPC-8) with compatible connectors Figure 3.6-2 Cover Installations Before field wiring, install the APS-6R plastic cover, and install the press-fit terminal block cover over TB1 when field wiring is complete (Figure 3.6-2). Figure 3.6-3 Typical APS-6R Wiring 1-48 Installation 15088:J 10/22/99

Connecting Multiple APS-6R Power Supplies Figure 3.6-4 shows typical trouble bus connections for multiple APS-6R power supplies using trouble connectors J3 and J4. Notes: 1. Use Cable 71033 or 75098 (same cables, different lengths) for all wiring. 2. APS-6R J3 and J4 can be interchanged. Figure 3.6-4 Trouble Bus Connections for Multiple APS-6R Power Supply Configuration Installation 15088: J 10/22/99 1-49

Section 3.7 The Central Processing Unit (CPU-2020, CPU-2) The Central Processing Unit is the heart of the system (refer to Figure 3.7-1). This unit directs all communications between modules and monitors all modules in the system for removal or failure. The CPU maintains all programmable system parameters (except alphanumeric information) in nonvolatile memory to protect the data if primary and secondary power is removed (provided the board and all associated cabling is handled with proper precaution). The CPU executes all control-by-event programs for specific action in response to an alarm condition. A real-time clock provides time annotation on the display(s), history file, and printer. The CPU provides one set of Form-C general alarm contacts and one set of Form-C system trouble contacts. The Form-C general alarm contacts will transfer during the presence of one or more fire alarm signals. The Form-C system trouble contacts will transfer during any security alarm supervisory signal or trouble condition. The Form-C trouble contacts will not transfer when both primary and secondary power is lost. When such transfer is required, use a separate, listed power supervisory relay. Only one CPU is required per AM2020/AFP1010 system. Note: Due to the proximity of the alarm and trouble contacts to CPU-based system control functions, only circuits that are unlikely to produce any electrical noise should be connected to the contacts. If a noise-generating device is connected to these contacts, system operation problems might be encountered. 11 No connection 10 No connection 9 No connection 8 Normally open contact 7 Normally closed contact 6 Common 5 4 No connection Normally open contact 2 Normally closed contact 1 Common P4 See Appendix A for contact ratings } } System Trouble/ Supervisory/ Security Contacts General Alarm Contacts Connect Terminal 5 of P4 to chassis ground via cable (Part Number 71073) Figure 3.7-1 CPU Alarm and Trouble Contacts NOTE Contacts may be connected to power-limited or nonpower-limited sources of power. Refer to the power-limited information label located inside the door of the FACP. All circuits that are connected to nonpower-limited sources of power must be identified on this label. 1-50 Installation 15088:J 10/22/99